JP2005094805A - Method for allocating common packet channel (cpch) in next-generation mobile communication - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for allocating a common packet channel in next-generation mobile communication, in which a common packet channel (CPCH) that is allocated in a base station is accurately used to transfer data by a user side. <P>SOLUTION: The method includes transmitting, at a base station (BS), of common packet channel control command information (CPCH Control Command) to user equipment (UE) through a dedicated physical channel (DPCH), when a power control preamble is transported from the user equipment; and transporting, at the user equipment, of a common packet channel message to the base station through the common packet channel, when the common packet channel control command (CCC) is received within a predetermined time. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to next-generation mobile communication, and more particularly to common packets in next-generation mobile communication suitable for accurate common packet channel (CPCH) allocation between a specific user side (UE) and a base station (BS) side. The present invention relates to a channel (CPCH) allocation method.

Recently, Japan's ARIB and TTC, European ETSI, US T1, and South Korea TTA have developed the Third Generation Partnership Project (hereinafter referred to as 3GPP) to technically standardize next generation mobile communication systems. For short).
For the Global Radio Access Network (UTRAN) in the research part of 3GPP, definitions and explanations for a transport channel and a physical channel are given.

  Here, a common packet channel (Common Packet Channel, CPCH) of the transfer channel is used when a relatively long data is transferred to the base station (BS) through the uplink (Up-Link, UL) on the user side (UE). It is assigned between the station (BS) and the user side (UE). At this time, the uplink (UL) common packet channel (CPCH) is associated with a dedicated channel (Dedicated Channel, DCH) that is a channel for performing closed loop power control. DCH) is mapped to a dedicated physical control channel (DPCCH) of the physical channel. Such a common packet channel (CPCH) is allocated to many users (UEs) in a random access (Random Access) scheme.

  At present, in 3GPP, when assigning a common packet channel (CPCH), it is important to assign a common packet channel (CPCH) efficiently in consideration of a case where a desired assigned channel collides.

  FIG. 1 is an explanatory diagram of a common packet channel (CPCH) transfer method according to the prior art, and FIG. 2 is a structural diagram of a downlink dedicated physical control channel (DL DPCCH) for the common packet channel (CPCH) according to the prior art. .

  As shown in FIG. 1, the common packet channel (CPCH) scheme uses a common packet channel state indication channel (CSICH: CPCH Status Indicator) for transferring the availability of the common packet channel (CPCH) provided by the base station and maximum transfer rate information. (Channel), PCPCH AP (Access Preamble Part) (hereinafter referred to as AP) requesting use of a specific physical common packet channel (PCPCH), AP-AICH (Access Preamble-Acquisition Indicator Channel) for transferring a response to the AP, collision detection and resolution PCPCH CD-P (Collision D for Collision Detection and Resolution) (Partition Preamble) part (CD-P), CD / C-P (Response Detection / Channel Assignment Indicator Channel) for response to CD-P and channel assignment, 0 to set the transfer power level before data transfer Alternatively, a PCCHH PC-P (Power Control Preamble) part (hereinafter referred to as PC-P) having a length of 8 slots, a DL DPCCH (Dedicated Physical Control) packet for providing inner loop power control (Inner loop power control), and It is composed of a PCPCH message part for transferring data. Here, the PCPCH message part is further divided into a PCPCH message data part and a PCPCH message control part.

  In 3GPP, the common packet channel (CPCH) operates in two modes.

  One of them is a UE (User Equipment) corresponding to the terminal, and a UE Channel Selection Method (UCSM) that selects the common packet channel (CPCH). The other is a Node B corresponding to the base station that uses the common packet channel (CPCH). This is a VCAM (Versatile Channel Assignment Method) to be allocated and notified to the UE.

  In the UCSM, a common packet channel state indication channel (CPCH Status Indicator Channel: hereinafter abbreviated as CSICH) periodically transfers the availability of each common packet channel (CPCH).

  In VCAM, the CSICH periodically transfers the availability of each common packet channel (CPCH) and the maximum transfer rate information.

  The access preamble (AP), collision detection preamble (CD-P), and AP-AICH transfer one of 16 symbols having a length of 16 (signature SET).

  In UCSM, an AP symbol indicates a specific channel. More specifically, the AP symbol refers to a scrambling code of a specific channel.

  In VCAM, the AP symbol indicates a desired data rate on the user side (UE). In VCAM, an AP symbol, a CD / CA-ICH symbol, and a code indicate a specific channel.

  Of the 16 symbol groups having different lengths of CD / CA-ICH, 8 are used for response to CD-P and the remaining 8 are used for channel allocation.

  CD / CA-ICH transfers one of eight symbols for CD-P response in the UCSM method, and one of the eight symbols for CD-P response and channel allocation in the VCAM method. Transfer one of the 8 symbols simultaneously. Therefore, in the VCAM system, two symbols are transferred simultaneously for different uses.

  The structure of the conventional downlink dedicated physical channel (DL DPCH) is as shown in FIG. The dedicated physical channel (DPCH) includes a dedicated physical control channel (DPCCH: Dedicated Physical Control Channel) and a dedicated physical data channel (DPDCH: Dedicated Physical Data Channel). In the conventional structure, DL DPCCH consists of pilot, TPC, and TFCI, and DL DPDCH consists only of data channel. TFCI is not used in DL DPCCH (DL DPCCH for CPCH) for the common channel used for CPCH. Also, DL DPDCH is not used.

  3a to 3c are views for explaining a normal packet channel transfer process according to the prior art.

  3a to 3c illustrate a common packet channel (CPCH) for a transport block set between a serving user radio network controller and a radio link control (SRNC-RLC) layer in a user radio link control layer (UE RLC). ) Shows the transfer process.

  First, the user side (UE) uses a radio resource control (RRC) procedure such as radio bearer setup (RADIO BEARER SETUP) or transfer channel reconfiguration (TRANSPORT CHANNEL RECONFIguration) for common packet channel (CPCH) transfer. Implement a packet channel (CPCH) configuration.

  That is, the user side (UE) MAC layer 2 requested for data transfer from the user side (UE) radio link control (RLC) layer 1 through the MAC-D-data-REQ is the user side (UE) L1 layer 3 for the first time. Request the status information of the common packet channel (CPCH) through PHY-CPCH-status-REQ. Such status information is broadcast over CSICH using a channelization code such as AP-AICH.

  The user side (UE) L1 layer 3 receives the state information from the CSICH and transmits it to the user side (UE) MAC layer 2 through the PHY-CPCH-state-CNF.

  From the CSICH information, the user side (UE) MAC layer 2 selects a transfer format for a common packet channel (CPCH) access request, performs a persistent check according to a persistent value, and specifies it. After a delay of a certain length of time, an access request is made to the user side (UE) L1 (3) through PHY-Access-REQ. At this time, the user side (UE) L1 (3) transfers the AP with the first power (P1). Subsequently, when a response to the AP cannot be received after a certain time, the AP is re-transferred with a second power (P2) higher than the first power (P1).

  The base station (Node B) L1 (4) that has received the AP from the user side (UE) L1 (3) informs this to the base station (Node B) RRC5, selects a specific symbol (signature) and passes through AP-AICH. The specific symbol is transferred to the user side (UE) L1 (3). At this time, whether or not an AP can be ACKed is determined by the AP-AICH code.

  The user side (UE) L1 (3) that has received the ACK through the AP-AICH transfers the CD-P to the base station (node-B) L1 (4). The base station (Node B) that receives the CD-P selects a specific symbol (signature) and transfers the CD / CA-ICH.

  In UCSM, CD / CA-ICH only responds to CD-P.

  In VCAM, CD / CA-ICH performs a response to CD-P and a channel assignment function. At this time, in the VCAM, such channel allocation information is scrambled for the PC-P and the common control channel message part (CPCH message data part, CPCH message data part) on the user side (UE) L1 (3). Define the code.

  The user side (UE) MAC layer 2 that has received the PHY-Access-CNF from the user side (UE) L1 (3) selects a common packet channel (CPCH) transfer format and creates a transfer block group, and then a PHY- Data transfer is requested through data-REQ.

  The user side (UE) L1 (3) that has received the PHY-data-REQ transfers the message after setting the 0 or 8-slot length transfer power control preamble (PC-P).

  Data transfer through the common packet channel (CPCH) continues until all data is transferred, or continues to the maximum frame length specified by the system.

  At this time, the ACK or NAK information of the radio network controller (RNC) RLC layer 8 is transmitted to the user side (UE) RLC1 through the FACH.

  As described above, points A to B in FIGS. 3a to 3c show a common packet channel (CPCH) transfer process for the first transfer block group, and points C and D in FIGS. 3a to 3c. In the figure, a common packet channel (CPCH) transfer process for transferring each successive transfer block group is shown.

  However, in the conventional common packet channel (CPCH) allocation method, when the common packet channel (CPCH) allocation information is erroneously received at the time of transfer, the common packet channel already in use is duplicated. Therefore, there is a problem that a communication service with a certain quality cannot be provided.

  That is, in FIG. 1, even if an error occurs in the common packet channel determination process, the user station (UE) does not know this and the base station passes through the common packet channel (CPCH) different from the assigned common packet channel (CPCH). There was a problem that it was not possible to prevent the malfunction situation of transferring data.

  SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and its purpose is to provide a common packet channel in next-generation mobile communication in which data can be transferred by accurately using a common packet channel (CPCH) assigned by a user at a base station. It is to provide an allocation method.

  In the common packet channel (CPCH) allocation method in the next generation mobile communication according to the present invention, the base station (BS) transmits the power control preamble from the user side through the dedicated physical channel (DPCH). Transmitting the common packet channel control command information (CPCH) to the base station side when the user side receives the common packet channel control command information (CCC) within a set time. It includes the step of transferring a packet channel message, thereby achieving the above object.

  The common packet channel control command (CCC) information may be message start indicator information that instructs the start of the common packet channel message between the base station and the user measurement.

  The message start indicator may be transferred to the user side if the user side transfers a transfer power preamble for setting a transfer level of the common packet channel message to the base station.

  The message start indicator may transfer a power control preamble (PC-P) for setting a transfer power level to the base station by the user side through the dedicated physical channel between a plurality of frames immediately after the transfer. .

  The common packet channel control command information may be composed of one slot, one frame, or two frames or more.

  The message start indicator may be inserted into a transfer format combination indicator (TFCI) field of the power control preamble and transmitted through the dedicated physical control channel (DPCCH).

  The field for transferring the common packet channel control command information to the user side may be used for measurement for channel estimation or power control when the common packet channel control command information is not transferred to the user side. Good.

  The user side may transfer the common packet channel message to the base station regardless of reception of the common packet channel control command (CCC) information when the transfer of the power control preamble to the base station is completed. .

  If the user side cannot receive the common packet channel control command information within a set time, the common packet channel message transfer being transferred to the base station may be interrupted immediately.

  The dedicated physical control channel (DPCCH) for the common packet channel in the downlink dedicated physical control channel from the base station to the user includes a pilot field, a transfer power control (TPC) field, a transfer format combination indicator (TFCI). ) Field and a common packet channel control command field.

  The transfer power control (TPC) field of the dedicated physical control channel for the common packet channel comprises at least 2 bits, the common packet channel control command field (CCC) comprises at least 4 bits, and the pilot field comprises at least It consists of 4 bits and the transfer format combination indicator (TFCI) field may not be used.

  The transfer power control (TPC) field, the transfer format combination indicator (TFCI) field, and the common packet channel control command field (CCC) of the dedicated physical control channel for the common packet channel are composed of at least 2 bits, The pilot field may consist of at least 4 bits.

  To achieve the above object, the present invention provides a common packet channel control command to a user side (UE) through a dedicated physical channel (DPCH) when a base station (BS) transmits a power control preamble from a user side. Transmitting information (CPCH Control Command); and receiving the common packet channel control command information (CCC) on the user side within a set time, the common packet channel message is transmitted to the base station side through a common packet channel. It is made including the step of transferring Gee.

  As described above, since the present invention can prevent the common packet channel (CPCH) already used by a specific user side (UE) from being used repeatedly, it is possible to provide a stable communication service. is there.

  Note that the present invention is not limited to the above-described embodiments, and it is obvious that those skilled in the art can make various modifications and implementations without departing from the technical concept described in the claims of the present invention. is there.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 4 is a diagram for explaining a common packet channel (CPCH) transfer method according to the present invention, and FIG. 5 illustrates a structure of a downlink dedicated physical control channel (DLCH for CPCH) for the common packet channel according to the present invention. FIG. 6 is a diagram illustrating a format of a downlink dedicated physical control channel for a common packet channel according to the present invention.

The common packet channel (CPCH) method according to the present invention is different from the conventional common packet channel (CPCH) method in that a message start indicator (Start) through a downlink dedicated physical channel (DL DPCH) as shown in FIG.
of Message Indicator). For this reason, in the present invention, as shown in FIG. 5, not only pilot and transmission power control (TPC) information but also a common packet channel control command is provided for the downlink dedicated physical channel (DL-DPCH). (CPCH Control Command: hereinafter abbreviated as CCC) Information is transferred together. This is not present in the conventional method, and the problems of the prior art can be solved.

  That is, the downlink dedicated physical control channel (DL DPCCH for CPCH) for the common packet channel of the present invention transfers only control information, and therefore the downlink dedicated physical control channel (DL DPDCH) is not used in the present invention. More specifically, in the present invention, the downlink dedicated physical control channel (DL DPCCH for CPCH) for the common packet channel is a pilot, transfer power control (TPC), transfer format combination indicator (hereinafter referred to as TFCI). (Abbreviated) and CC information. Here, the TFCI information is 0 bits and is not used.

  CCC is a general common packet channel (CPCH) control command or common packet channel (CPCH) control information, and specifically, a message start indicator is transmitted through a downlink dedicated physical channel (DL DPCH). The first layer L1 control information for the first layer L1 and the upper layer control information higher than the first layer L1. That is, the CCC may be the first layer L1 control information and command, or may be control information and commands of higher layers. At this time, the length of the CCC transferred through the CCC field may be a slot unit or a frame unit. For example, the CCC may be an instruction or information that is one slot long and may be an instruction or information of one frame or several frames. Such a CCC is transferred to the CCC field of the downlink dedicated physical control channel (DL DPCCH for CPCH) for the common packet channel. Each CCC corresponds to a specific sequence. Therefore, each CCC instruction or information is divided into different sequences. The system predetermines these sequence information, and transfers the sequence information during the system operation through control channels such as 3GPP system broadcast channel (BCH) and forward access channel (Forward Access Channel: FACH). it can.

  A message start indicator (hereinafter referred to as SMI), which is one of the CCCs, is several frame control information.

At this time, the base station uses the down dedicated physical control channel (DL) for the SMI transfer.
A specific sequence for SMI is transferred between several frames in the CCC field of (DPCCH). The base station system can determine a sequence for SMI in advance, and transfer the sequence information through a control channel such as 3CHP system BCH) or FACH. The sequence for SMI can be any arbitrary sequence. For example, there are [0000], [1111], [1010], [0101], [1100], [0011], etc. that are repeatedly transferred for each slot.

  For example, the 0 or 8 slot length of the up CPCH is transferred between several frames immediately after the power control preamble (PC-P), and the [1010] sequence is transferred between several frames repeatedly for each slot.

  The transfer length of the SMI sequence is also determined in advance, and transferred through a control channel such as BCH or FACH of the 3GPP system.

  If some CCC information or command is not transferred through the CCC field, nothing is transferred to the CCC field or a specific pattern is transferred. This particular pattern is used for measurements for channel estimation or power control.

  7a to 7c are views for explaining a normal common packet channel transfer process according to the present invention.

First, the user side (UE) performs radio bearer setup (RADIO BEARER SETUP) or transfer channel reconfiguration (TRANSPORT CHANNEL).
Through a radio resource control (RRC) procedure such as RECONFIGURATION, a common packet channel (CPCH) configuration for the transfer of the common packet channel (CPCH) is implemented.

  That is, the user side (UE) MAC layer 22 requested to transfer data from the radio link control (RLC) layer 21 on the user side (UE) through the MAC-D-data-REQ is the user side (UE) L1 layer 23 for the first time. Request the status information of the common packet channel (CPCH) through PHY-CPCH-status-REQ. Such status information is broadcast over CSICH using a channelization code such as AP-AICH.

  The user side (UE) L1 layer 23 receives state information from the CSICH and transmits it to the user side (UE) MAC layer 22 through the PHY-CPCH-state-CNF.

  From the CSICH information, the user side (UE) MAC layer 22 selects a transfer format for a common packet channel (CPCH) access request, performs a persistent check according to a persistent value, and identifies it. After the delay of the length of, access request is made to the user side (UE) L1 (23) through PHY-Access-REQ. At this time, the user side (UE) L1 (23) transfers the AP with the first power (P1). Subsequently, when a response to the AP cannot be received after a certain time, the power is increased and the AP is retransmitted with the second power (P2).

  The base station (Node B) L1 (24) that received the AP from the user side (UE) L1 (23) informs this to the base station (Node B) RRC (25), selects a specific symbol, and AP-AICH Through the user side (UE) L1 (23). At this time, whether or not ACK is possible for the AP is determined by the AP-AICH code.

  The user side (UE) L1 (23) that has received the ACK through the AP-AICH transfers the CD-P to the base station (node-B) L1 (24). The base station (Node B) that has received the CD-P selects a specific symbol and transfers the CD / CA-ICH. In UCSM, CD / CA-ICH only responds to CD-P.

  In VCAM, CD / CA-ICH performs a response to CD-P and a channel assignment function. At this time, in the VCAM, such channel allocation information is scrambled for the PC-P and the common control channel message part (CPCH message data part, CPCH message control part) at the user side (UE) L1 (23). Define the code.

  The user side (UE) MAC layer 22 that has received the PHY-Access-CNF from the user side (UE) L1 (23) selects a common packet channel (CPCH) transfer format and creates a transfer block group, and then a PHY- Data transfer is requested through data-REQ.

  The user side (UE) L1 (23) that has received the PHY-data-REQ transfers the message after setting the 0 or 8-slot length transfer power control preamble (PC-P).

  Data transfer through the common packet channel (CPCH) continues until all data is transferred, or up to the maximum frame length specified by the system.

While the first transfer block is transferred, the base station (Node B) L1 (24) transfers a message start indicator to the user side (UE) L1 (23). The user side (UE) L1 (23) determines whether or not the correct common packet channel (CPCH) has been opened depending on whether or not the message start indicator is received. If the user side (UE) L1 (23) cannot receive the message start indicator during the preset (promise) time, the common packet channel (CPCH) message transfer is interrupted immediately. Otherwise, the user side (UE) L1 (23) continues message transfer. More specifically, the user side (UE) L1 (23) is a downlink dedicated physical control channel (DL for CPCH) for a common packet channel between Nsmi frames after the power control preamble (PC preamble).
A message start indicator transferred to the DPCCH is received. If the user side (UE) L1 (23) fails to receive a message start indicator during the Nsmi frame promised in advance, the user side (UE) L1 (23) suspends the common packet channel (CPCH) message transfer; The user side (UE) MAC 22 is notified of the failure message.

  However, when the user side (UE) L1 (23) receives the message start indicator during the Nsmi frame promised in advance, the user side (UE) L1 (23) continues to transfer the message. Here, the Nsmi frame value is system information, and is transferred in advance to the user side (UE) L1 (23) through a control channel such as a broadcast channel (BCH) or an up access channel (FACH).

  On the other hand, ACK (Acknowledgement) or NAK (Non-acknowledgement) information of a radio network control (RNC) radio link control (RLC) layer 28 is transmitted to a user side (UE) RLC 21 through an up access channel (FACH).

  Points A to B in FIGS. 7a to 7c show a common packet channel (CPCH) transfer process for a transport block set transferred first. 7A to 7C show a common packet channel (CPCH) transfer process for transferring a continuous transfer block group (Transport Block Set).

  FIG. 8 is a diagram illustrating a second format of a downlink dedicated physical control channel (DL DPCCH for CPCH) for a common packet channel (CPCH) according to the present invention.

  The second format of the downlink dedicated physical control channel (DL DPCCH for CPCH) for the common packet channel (CPCH) according to the present invention is similar to the first format shown in FIGS. Indicates that the downlink dedicated physical control channel (DL DPCCH) has a transfer format combination indicator (TFCI) bit of 2 bits, and a common packet channel control command (CPCH Control Command: CCC) field of 2 bits.

  That is, FIG. 8 is a diagram illustrating a second format of a downlink dedicated physical control channel (CPCH DL DPCCH) for a common packet channel according to the present invention. Note that the TFCI field can be used for common packet channel control (CPCH control) information transfer in the first layer L1 and higher layers.

  If the TFCI field is used for common packet channel control (CPCH control) information transfer, control information expressed in a general sequence is transferred as in the common packet channel control command (CCC) field. For example, control information represented by a TFCI codeword can be transferred using TFCI encoding and a TFCI mapping method for a physical channel. At this time, although the information transferred to the TFCI field is common packet channel (CPCH) control information, the physical operation method operates in the same manner as TFCI.

  The information transferred to the TFCI field and the information transferred to the CCC field can be transferred at the same time, or not transferred at the same time. If not configured to be transferred at the same time, a 4-bit sequence for a message start indicator (hereinafter, abbreviated as SMI) is a 4-bit CCC with a 2-bit TFCI and 2-bit CCC field as one 4-bit field. Transfer in the same way as for the field.

  If configured to be transferred at the same time, the sequence for the message start indicator (SMI) and emergency interruption (ES) is per slot along with [11], [00], [10], [01], etc. It consists of 2 bits and is transferred to the 2-bit CCC field. The 2-bit CCC operation method is the same as the 4-bit CCC operation method described above except that the sequence length per slot is 2 bits.

It is a figure for demonstrating the transfer system of the common packet channel (CPCH) by a prior art. FIG. 2 is a diagram illustrating a structure of a downlink dedicated physical control channel (DL DPCCH) for a common packet channel (CPCH) according to the prior art. FIG. 10 is a diagram for explaining a normal common packet channel transfer process according to the prior art. FIG. 10 is a diagram for explaining a normal common packet channel transfer process according to the prior art. FIG. 10 is a diagram for explaining a normal common packet channel transfer process according to the prior art. FIG. 3 is a diagram for explaining a common packet channel (CPCH) transfer method according to the present invention; FIG. 6 is a diagram illustrating a structure of a downlink dedicated physical control channel (DLCH for CPCH) for a common packet channel according to the present invention. FIG. 6 is a diagram illustrating a format of a downlink dedicated physical control channel (CPCH DL DPCCH) for a common packet channel according to the present invention; FIG. 5 is a diagram illustrating a normal common packet channel transfer process according to the present invention. FIG. 5 is a diagram illustrating a normal common packet channel transfer process according to the present invention. FIG. 5 is a diagram illustrating a normal common packet channel transfer process according to the present invention. FIG. 6 is a diagram illustrating a second format of a downlink dedicated physical control channel (CPCH DL DPCCH) for a common packet channel (CPCH) according to the present invention;

Claims (54)

A method for transmitting data on a common packet channel CPCH in a communication network, comprising:
Transmitting a predetermined sequence of bits from the base station to the user equipment via the dedicated physical control channel DPCCH;
Detecting a predetermined sequence of the plurality of bits for transmitting data from the user equipment to the base station via a common packet channel.   The method of claim 1, wherein the predetermined sequence of bits is provided in one frame, the frame comprising 15 slots.   The method of claim 1, wherein the data is packet data.   The method of claim 1, wherein the predetermined sequence of bits is received within a predetermined period of time while the start of data transmission is detected by the user equipment.   The method of claim 1, wherein the user equipment stops the data transmission if the predetermined sequence of the plurality of bits is not received within a predetermined period of time.   The method of claim 1, wherein the predetermined sequence of the plurality of bits is transmitted when a power control preamble is sent from the user equipment.   The method of claim 1, wherein the predetermined sequence of bits comprises 4 bits.   The method according to claim 1, 2, 5 or 6, wherein the four bits of the predetermined sequence are [1111], [1100] or [1001].   The method according to claim 1, 2, 5 or 6, wherein the 4 bits of the predetermined sequence are [1010].   3. The method of claim 2, wherein the frame includes at least one of a pilot field, a transfer power control TPC field, or a transfer format combination identifier TFCI.   The method of claim 10, wherein the pilot field is at least 4 bits and each of the TPC field and TFCI is at least 2 bits.   The method according to claim 10 or 11, wherein the predetermined sequence of the plurality of bits is provided in the TFCI. A communication network adapted to provide a plurality of frames on a dedicated physical control channel DPCCH, each frame including a plurality of slots, wherein at least one slot is a plurality to support a common packet channel transmission. A predetermined sequence of bits of
The communication network, wherein the predetermined sequence of bits is used to determine whether to transmit data over a common packet channel or to interrupt transmission of data over the common packet channel.   14. The network of claim 13, wherein the frame includes at least one of a pilot field, a transfer power control TPC field, or a transfer format combination identifier TFCI.   The network of claim 13, wherein the predetermined sequence of bits includes 4 bits.   The network of claim 13, wherein the predetermined sequence of bits includes [1111].   The network of claim 13, wherein the predetermined sequence of bits includes [1010].   The network of claim 14, wherein the predetermined sequence of bits is provided in the TFCI.   The network of claim 13, wherein the plurality of slots includes 15 slots.   The network of claim 13, wherein the data includes packet data. Means for receiving a power control preamble;
Means for providing at least one frame over a downlink dedicated physical control channel DL DPCCH, wherein the at least one frame is transmitted over the DL DPCCH to support common packet channel transmission; Means having a predetermined sequence of bits, and
The base station, wherein the predetermined sequence of bits is used to determine whether to transmit data over the common packet channel or to interrupt transmission of data over the common packet channel.   The at least one frame includes a plurality of slots, the at least one frame having at least one of a pilot field, a transfer power control TPC field, or a transfer format combination identifier TFCI. The listed base station.   The base station according to claim 22, wherein the plurality of slots includes 15 slots.   The base station according to claim 22, wherein the predetermined sequence of the plurality of bits is provided in the TFCI.   The base station according to any one of claims 21 to 24, wherein the predetermined sequence of the plurality of bits includes [1111].   The base station according to any one of claims 21 to 24, wherein the predetermined sequence of the plurality of bits includes [1010].   The base station according to claim 21, wherein the data is packet data. Means for generating a power control preamble;
Means for receiving and detecting a predetermined sequence of bits transmitted over a downlink dedicated physical control channel for a common packet channel CPCH;
Means for transmitting data via the CPCH,
User equipment wherein detection of the predetermined sequence of bits is used to determine whether the data is transmitted over the CPCH.   29. The user equipment of claim 28, wherein the predetermined sequence of bits includes 4 bits.   30. The user equipment according to claim 28 or 29, wherein the predetermined sequence of the plurality of bits is [1111].   30. The user equipment according to claim 28 or 29, wherein the predetermined sequence of the plurality of bits is [1010].   29. The user equipment of claim 28, wherein the predetermined sequence of the plurality of bits is received within a predetermined period between the start of data transmission.   30. The user equipment of claim 28, wherein the predetermined sequence of the plurality of bits is provided within one frame of the dedicated physical control channel.   34. The user equipment of claim 33, wherein the frame includes 15 slots. A frame carried on a dedicated physical channel of a communication network, the frame being
A plurality of slots, wherein a predetermined sequence of bits is provided in the frame to support common packet channel transmission;
The predetermined sequence of bits is used to determine whether data is transmitted over a common packet channel.   36. The frame of claim 35, wherein the predetermined sequence of bits includes 4 bits.   37. A frame according to claim 35 or 36, wherein the predetermined sequence of the plurality of bits is [1111].   37. A frame according to claim 35 or 36, wherein the predetermined sequence of the plurality of bits is [1010].   36. The frame of claim 35, wherein the plurality of slots includes 15 slots. A method of transmitting data on a common packet channel CPCH in a mobile communication system, comprising:
Transmitting a predetermined sequence of bits over a dedicated physical channel DPCH at a base station;
Receiving by the base station data transmitted from the user equipment via the CPCH;
A method of determining whether detection of a predetermined sequence of the plurality of bits by the user equipment initiates the data transmission on the CPCH by the user equipment.   41. The method of claim 40, wherein the DPCH includes a downlink dedicated physical control channel DL-DPCCH, and the predetermined sequence of the plurality of bits is provided in at least one frame of the DL-DPCCH.   42. The method of claim 41, wherein the predetermined sequence of bits is provided in a common packet channel control command CCC field of the at least one frame.   43. The method of claim 42, wherein the at least one frame includes 15 slots, each slot having a CCC field.   41. The method of claim 40, wherein prior to transmitting the predetermined sequence of bits, the user equipment transmits at least one preamble information to the base station.   45. The method of claim 44, wherein the at least one preamble includes a power control preamble.   46. The method of claim 40, 41, 42, 43, 44 or 45, wherein the predetermined sequence of bits is a 4-bit [1111] pattern.   46. The method of claim 40, 41, 42, 43, 44 or 45, wherein the predetermined sequence of bits is a 4-bit [1010] pattern. A method for accessing a common packet channel CPCH by a mobile communication device, comprising:
Receiving at the user equipment UE a predetermined sequence of bits within a predetermined period of start of accessing the CPCH via the dedicated physical control channel DPCCH;
Detecting whether the predetermined sequence of the plurality of bits corresponds to a [1010] pattern;
The method wherein access to the CPCH is interrupted if the [1010] pattern is not detected.   49. The method of claim 48, wherein the predetermined sequence of bits is provided within one frame of the DPCCH, the frame comprising 15 slots.   49. The method of claim 48, wherein the predetermined sequence of bits is received after a power control preamble is transmitted by the user equipment.   50. The method of claim 49, wherein the frame includes a pilot field, a transfer power control TPC field, and / or a transfer format combination identifier TFCI.   52. The method of claim 51, wherein the pilot field is at least 4 bits and each of the TPC field and TFCI is at least 2 bits.   53. A method according to claim 51 or 52, wherein the predetermined sequence of the plurality of bits is provided in the TFCI.   49. The method of claim 48, wherein if the UE detects a [1010] pattern, the UE continuously transmits data on the CPCH.

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